ES2420983T3 - Hermetic compressor - Google Patents

Abstract

A hermetic compressor comprising: - a hermetic container (101) including a suction tube (114) through which refrigerant is drawn and accommodating a compression mechanism unit for compressing the refrigerant; - a suction silencer (113) fixed to the compression mechanism unit and reducing the noise of the flow when the refrigerant passes; and - a connector (120) that allows the suction tube (114) and the suction silencer (113) to communicate with each other and that includes a hole (121) in a passage of the refrigerant to communicate with an interior space of the hermetic container ( 101), characterized in that - the connector (120) comprises a trumpet-shaped corrugated part in contact with the internal surface of the hermetic container (101) and a cylindrical flat part extending from the corrugated portion to communicate with the suction silencer (113), wherein the hole (121) provided in the connector (120) is provided in the flat cylindrical portion.

Description

Hermetic compressor

[Technical field]

The present invention is about a hermetic compressor and, more particularly, about a hermetic compressor that can reduce noise by regulating the suction pressure in a connector that allows a suction tube of an airtight container and a suction silencer to be communicate with each other.

[Background Technique]

In general, a hermetic compressor includes a compression mechanism unit that compresses refrigerant by a reciprocating motion, a motor mechanism unit that supplies power to the compression mechanism unit, and an airtight container that accommodates the unit of the compression mechanism. compression and motor mechanism unit in a tight state. The hermetic compressor, which is a component that constitutes a cooling system, such as a refrigerator, etc., serves to change phase a low temperature and low pressure gas refrigerant by passing it to high temperature and high pressure gas refrigerant. Such phase change can be implemented by the compression force of a piston with a reciprocating linear motion in a cylinder.

FIG. 1 is a view of an example of a conventional hermetic compressor and FIG. 2 is a graph of the noise and coolant speed in the example of the conventional hermetic compressor.

As illustrated in FIG. 1, in the conventional hermetic compressor, a given lower container 1a and a given upper container 1b are coupled to constitute an airtight container 1; a motor mechanism unit 4 composed of a stator 2 and a rotor 3 is installed in the airtight container 1; and a plurality of compression components are installed in the upper part of the unit 4 of the engine mechanism. Several springs S are supported on the lower side of the stator 2 to absorb the shocks applied to the stator 2 during the rotation of the rotor 3, and the components for transferring power are installed between the unit 4 of the motor mechanism and the compression components.

Components for power transfer include a rotating shaft 5, a cylinder block 6, a jacket 7 and a connecting rod 8. The rotating shaft 5 is snapped into a snap-in hole 3a that penetrates through the center of the rotor 3 in the vertical direction and inserted with rotation in the block 6 of the cylinder. An eccentric portion 5a provided in an upper end portion of the rotating shaft 5 is coupled to the sleeve 7 and the connecting rod 8, which converts a rotary movement into a linear motion, is coupled to the sleeve 7.

Compression components include a cylinder 9 and a piston 10. Cylinder 9 is provided on one side of the upper portion of the cylinder block 6, and the piston 10 is inserted into the cylinder 9 and connected to the connecting rod 8 to be subjected to a reciprocating linear movement. Here, a valve device 11 for use in the aspiration / discharge of refrigerant gas from / into a compression space of the cylinder 9 is coupled with an opening portion to one side of the cylinder 9, and a cylinder head cover 12 divided into A suction space and a discharge space for separating the suction refrigerant from the discharge refrigerant is coupled to the outside of the valve device 11. In addition, a suction silencer (not shown) is coupled to the bottom side of the cylinder head cover 12 to communicate with it. The suction silencer communicates with a suction tube 14 provided in the airtight container 1 through a connector (not shown). In addition, it can provide a discharge silencer (not shown) to reduce the noise of the discharge refrigerant on the upper side of the cylinder head cover 12 to communicate with it. The discharge silencer communicates with a discharge tube 15 provided in the airtight container 1 through a link pipe 16.

The operation of the hermetic compressor will be described. When power is applied to the unit 4 of the rotor mechanism, the rotor 3 rotates due to the interaction between the stator 2 and the rotor 3, and the rotating shaft 5 coupled to the rotor 3 is rotated. As the rotation of the rotating shaft 5 it is converted into a linear reciprocating movement by the connecting rod 8, the piston 10 is subjected to a linear reciprocating movement in the compression space of the cylinder 9. Here, when the piston 10 moves backwards, refrigerant is introduced into the device 11 of the valve through the suction silencer and the suction space of the cylinder head cover 12 by means of the suction tube 14. When a suction valve (not shown) of the valve device 11 is open, the refrigerant is sucked into the compression space of the cylinder 9.

Then, when the piston 10 moves forward, the compressed refrigerant in the compression space opens a discharge valve (not shown), is discharged into the discharge space of the cylinder head cover 12 and is discharged to the outside through the discharge tube 15 of the sealed container 1 through the discharge silencer and the link pipe 16.

In the conventional hermetic compressor described above, the adhesion of the connector is designed to be greater than the internal pressure of the suction tube, so that the elastic connector is closely

fixed inside the airtight container. Therefore, although the refrigerant varies, the internal pressure of the tube is kept relatively low. For example, in the case of an hermetic compressor that uses refrigerant 600a, a suction pressure of Ps is maintained at -42.17 kPa, which is a negative pressure (-pressure) and, in the case of an hermetic compressor that uses refrigerant 134a, a suction pressure Ps is maintained at 13.73 kPa, which is a positive pressure (+ pressure).

Consequently, in the conventional hermetic compressor, since the suction pressure is significantly lower than the compression space pressure, as shown in FIG. 2, the coolant suction speed is high (9 m / sec2), but the coolant noise in specific frequency bands such as 4 k is high (approximately 28 dBA). Consequently, there is a need to improve the soundproofing performance.

WO 2006/109239 A1 discloses a compressor according to the preamble of claim 1 which comprises a housing that includes a suction tube through which refrigerant is aspirated and that accommodates a compression mechanism unit for compressing the refrigerant. A suction silencer is attached to the unit of the compression mechanism and reduces the flow noise when the refrigerant passes. A connector allows the suction tube and the suction silencer to communicate with each other and includes a hole in a coolant passage to communicate with an interior space of the container. In addition, the connector comprises a cylindrical flat part having an inlet part into which the sliding suction tube is inserted. An attenuation cavity having a diameter greater than the cylindrical flat part extends from it and grabs an inlet tube to the suction silencer silencer by touching just a thin circular line of its outer surface a little behind the end of the inlet tube to the muffler. The hole is provided in the attenuation cavity next to the side of the outlet opening.

[Divulgation]

[Technical problem]

The present invention has been carried out in an effort to solve the prior art problems described above, and an object of the present invention is to provide a hermetic compressor that can regulate the suction pressure of the refrigerant to improve the performance of the soundproofing.

[Technical solution]

This object is solved by means of the hermetic compressor according to claim 1. An hermetic compressor includes: an hermetic container that includes a suction tube through which refrigerant is aspirated and that accommodates a compression mechanism unit to compress the refrigerant; a suction silencer attached to the unit of the compression mechanism and which reduces the flow noise when the refrigerant passes; and a connector that allows the suction tube and the suction silencer to communicate with each other and that includes a hole in a passage of the refrigerant to communicate with an interior space of the airtight container.

In addition, the number of the hole provided in the connector is set such that the difference between the internal pressure of the connector and the internal pressure of the sealed container is below an established pressure.

Similarly, the size of the hole provided in the connector is set such that the difference between the internal pressure of the connector and the internal pressure of the sealed container is below an established pressure.

In addition, the location of the hole provided in the connector is established such that the difference between the internal pressure of the connector and the internal pressure of the airtight container is below an established pressure.

Also, the hole provided in the connector is located adjacent to an inlet of the suction silencer.

Also, the corrugated part of the connector is closely connected to an inner surface of the airtight container that communicates with the suction tube, and the flat part of the connector is snapped into the suction silencer.

Also, the connector is formed of a rubber material.

[Advantageous effects]

In the hermetic compressor according to the present invention, even if the refrigerant is aspirated with a low suction pressure through the suction tube of the hermetic container, the connector and the suction silencer, the suction pressure of the connector is equalized with the internal pressure of the airtight container by means of the hole provided in the connector. Thus, the coolant suction pressure is raised and the coolant speed is reduced. There is the advantage that it can improve the soundproofing performance in specific frequency bands.

[Description of the drawings]

FIG. 1 is a view of an example of a conventional hermetic compressor. FIG. 2 is a graph of the noise and coolant speed in the example of the hermetic compressor conventional. FIG. 3 is a view of an embodiment of a hermetic compressor according to the present invention. FIG. 4 is a view of a refrigerant suction noise reduction structure in the embodiment of the hermetic compressor in which, however, the flat part of the connector is not cylindrical. FIG. 5 is a graph of the noise and coolant speed in the realization of the hermetic compressor according to the present invention.

[Best embodiment of the invention]

Exemplary embodiments of the present invention will now be described in detail with reference to the accompanying drawings.

As illustrated in FIGURES 3 and 4, in the embodiment of the hermetic compressor, a given lower container 101 and a given upper container (not shown) are coupled to constitute an airtight container (hereinafter referred to by reference number 101 of the bottom vessel), and a set a stator 102, a rotor (not shown), a rotating shaft 105, a cylinder block 106, a cylinder 109, a piston (not shown), a valve device (not shown), a cylinder head cover 112 and a suction silencer 113 are installed in the airtight container 101. The respective components are in the public domain and, therefore, their detailed description will be omitted. A suction tube 114 is provided, which guides the refrigerant to be sucked into the airtight container 101, and a discharge tube 115, which guides the refrigerant to be discharged out of the airtight container 101. The muffler 113 of suction and suction tube 114 communicate with each other through a connector 120 formed of a given elastic material.

Suction silencer 113 includes two covers coupled to each other that define an internal noise space, and a bent tube accommodated inside. The suction silencer 113 not only reduces the noise of the suction coolant, but also prevents the heating of the suction coolant when it is sucked into the cylinder 109 through the cylinder head cover 112.

The connector 120 is formed of a given rubber material with elasticity. One end of the connector 120 is a cylindrical flat portion and the other end thereof is a corrugated trumpet shaped portion. Here, the flat part of the connector 120 is coupled between the covers of the suction silencer 113 to engage with it and installed to communicate with the bent tube of the suction silencer 113. The corrugated part of the connector 120 is brought into contact with the inside of the airtight container 101 to communicate with the suction tube 114. The connector 120 can be bent at a given angle according to the location of an inlet of the suction silencer 113 and the suction tube 114.

A hole 121 is provided in the connector 120, which allows an interior space of the connector 120 and an interior space of the airtight container 101 to communicate with each other. Through the hole 121 an internal pressure of the connector 120 can be equalized with an internal pressure of the sealed container 101. Accordingly, to equalize the internal pressure of the connector 120 with the internal pressure of the sealed container 101 within a preset pressure according to the conditions of operation, the number and size of the holes 121 and the location of the hole 121 in the connector 120 can be determined in various ways. For example, preferably, one or more holes 121 are provided in the flat part of the connector 120 connected to the inlet of the suction silencer 113 so that they are adjacent to the inlet of the suction silencer 113. The hole 121 may be provided in the corrugated part of the connector 120. However, if the hole 121 is located in the corrugated part of the connector 120, since the suction pressure of the refrigerant is kept relatively low, the corrugated part of the connector 120 is tightly attached to the inner surface of the sealed container 101 and folded. This can interrupt the rapid equalization between the internal pressure of the connector 120 and the internal pressure of the airtight container 101. In addition, the internal pressure of the side of the corrugated part of the connector 120 is equalized with the internal pressure of the airtight container 101, which reduces the adhesion of the corrugated part of the connector 120 to the inside of the airtight container 101.

This leads to a loss of refrigerant flow.

The operation of the hermetic compressor according to the present invention will be described.

When power is applied to a motor mechanism unit (not shown), the rotor (not shown) rotates due to the interaction between stator 102 and the rotor. As the rotational force of the rotor is converted into a linear reciprocating motion of the piston (not shown), the piston is subjected to a linear reciprocating motion in a compression space of the cylinder 109. Here, when the piston moves To the rear, refrigerant is introduced into the valve device (not shown) through the suction tube 114, the connector 120, the suction silencer 113 and a suction space of the cylinder head cover 12. When a suction valve (not shown) of the valve device is open, the refrigerant is sucked into the compression space of the cylinder 109.

Then, when the piston 10 moves forward, the compressed refrigerant in the compression space opens a discharge valve (not shown), is discharged into a discharge space of the cylinder head cover 112 and is discharged to the outside through the tube 115 of discharge of the hermetic container 101 through the discharge silencer (not shown) and the link pipe (not shown).

5 When the hermetic compressor is operated as described above, heat is generated due to the operation of the engine mechanism unit and the movement of the piston. Although the internal pressure of the airtight container 101 remains relatively high, the pressure of the coolant aspirated through the suction tube 114, the connector 120 and the suction silencer 113 remains lower than the internal pressure of the hermetic container

101. However, the pressures are equalized by the hole 121 of the connector 120. That is, the internal pressure

10 of the sealed container 101 decreases and the internal pressure of the connector 120 increases. Therefore, even if the suction pressure is kept low according to the operating conditions, it can be matched with the internal pressure of the airtight container 101. As the suction pressure increases, the coolant suction speed is reduced, proportional to the difference between the compression space pressure and the suction pressure. However, the refrigerant suction noise of specific frequency bands can be reduced.

15 FIG. 5 is a graph of the noise and coolant speed in the embodiment of the hermetic compressor according to the present invention. In the hermetic compressor operated as described above, although the suction pressure is kept low according to the operating conditions, it is equalized with the internal pressure of the hermetic container. As illustrated in FIG. 5, the coolant suction speed is 8 m / sec2, which is slightly lower than 9 m / sec2 of the conventional hermetic compressor, but the coolant noise in bands

20 specific frequencies such as 4 k is approximately 18 dBA, which is much less than the approximately 28 dBA of the conventional hermetic compressor. Obviously it improves the soundproofing performance.

Claims (6)

1. A hermetic compressor comprising: ! an airtight container (101) that includes a suction tube (114) through which refrigerant is aspirated and that accommodates a compression mechanism unit for compressing the refrigerant; 5 ! a suction silencer (113) fixed to the unit of the compression mechanism and that reduces the noise of the flow when the refrigerant passes; Y ! a connector (120) that allows the suction tube (114) and the suction silencer (113) to communicate with each other and that includes a hole (121) in a passage of the refrigerant to communicate with an interior space of the airtight container ( 101), 10 characterized in that ! The connector (120) comprises a trumpet shaped corrugated part in contact with the inner surface of the airtight container (101) and a cylindrical flat part extended from the corrugated portion to communicate with the suction silencer (113), in which the hole (121) provided in the connector (120) is provided in the cylindrical flat portion. 2. The hermetic compressor of claim 1 wherein the hole number (121) provided in the connector (120) is set such that the difference between the internal pressure of the connector (120) and the internal pressure of the container Hermetic (101) is below an established pressure. 3. The hermetic compressor of claim 1 or 2 wherein the hole size (121) provided in the connector (120) is established in such a way that the difference between the internal pressure of the connector (120) and the internal pressure of the airtight container (101) is below an established pressure. 4. The hermetic compressor of any one of claims 1 to 3 wherein the location of the hole (121) provided in the connector (120) is established such that the difference between the internal pressure of the connector (120) and the internal pressure of the airtight container (101) is below an established pressure.

5.

The hermetic compressor of any one of claims 1 to 4 wherein the hole (121) 25 provided in the connector (120) is located adjacent to an inlet of the suction silencer (113).

6. The hermetic compressor of claim 1 wherein the corrugated part of the connector (120) is closely connected to an inner surface of the hermetic container (101) communicating with the suction tube (114), and the flat part of the connector (120) is snapped into the suction silencer (113).

7.

The hermetic compressor of any one of claims 1 to 6 wherein the connector (120) is formed of a rubber material.